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When grouped together, bytes can contain the information to form a document, such as a photograph or a book. All information stored on a computer is composed of bytes, from e-mails and pictures, to programs and data stored on a [[hard drive]]. Although initially it may appear to be a simple concept, the actual definition is far more complex and profound.
When grouped together, bytes can contain the information to form a document, such as a photograph or a book. All information stored on a computer is composed of bytes, from e-mails and pictures, to programs and data stored on a [[hard drive]]. Although initially it may appear to be a simple concept, the actual definition is far more complex and profound.


A byte is really just an 8-digit [[binary numeral system|binary]] number, but the [[semantics]], or meaning assigned to a given byte, is a matter defined within the [[instruction set architecture]] (ISA) of each type of computer.  Many different encodings have been tried for text, for integers, and for various non-integer numbers.  A discussion of the merits of the various representations is complex and falls under the field of [[computer architecture]].  The topic of [[text encoding]] is particularly tricky.  Various systems for encoding printable characters have been used, including [[American Standard Code for Information Interchange|ASCII]], [[Extended Binary Coded Decimal Interchange Code|EBCDIC]], and various flavors of [[Unicode|Unicode Character Encoding]].
A byte is a [[binary numeral system|binary]] number, but the [[semantics]], or meaning assigned to a given byte, is a matter defined within the [[instruction set architecture]] (ISA) of each type of computer.  Many different encodings have been tried for text, for integers, and for various non-integer numbers.  A discussion of the merits of the various representations is complex and falls under the field of [[computer architecture]].  The topic of [[text encoding]] is particularly tricky.  Various systems for encoding printable characters have been used, including [[American Standard Code for Information Interchange|ASCII]], [[Extended Binary Coded Decimal Interchange Code|EBCDIC]], and various flavors of [[Unicode|Unicode Character Encoding]].


In the early [[history of computing]], experimental computers were built containing alternates numbers of byte sizes, including (for example) nine bits (binary digits) per byte.
In the early [[history of computing]], experimental computers were built containing alternates numbers of byte sizes, including (for example) nine bits (binary digits) per byte.

Revision as of 15:32, 22 September 2007

The Hexer hex editor displaying the Linux kernel version 2.6.20.6; this image illustrates the value of bytes composing a program as they appear in the hexadecimal format

In computer science, a byte is a unit of data consisting of (usually) eight binary digits, each of which is called a bit. The 8-bit byte is the smallest addressable unit of information in the instruction set architecture (ISA) of most electronic computers today.

When grouped together, bytes can contain the information to form a document, such as a photograph or a book. All information stored on a computer is composed of bytes, from e-mails and pictures, to programs and data stored on a hard drive. Although initially it may appear to be a simple concept, the actual definition is far more complex and profound.

A byte is a binary number, but the semantics, or meaning assigned to a given byte, is a matter defined within the instruction set architecture (ISA) of each type of computer. Many different encodings have been tried for text, for integers, and for various non-integer numbers. A discussion of the merits of the various representations is complex and falls under the field of computer architecture. The topic of text encoding is particularly tricky. Various systems for encoding printable characters have been used, including ASCII, EBCDIC, and various flavors of Unicode Character Encoding.

In the early history of computing, experimental computers were built containing alternates numbers of byte sizes, including (for example) nine bits (binary digits) per byte.

Definition of byte

In electronics, information is represented by the toggle of two states, usually referred to as 'on' and 'off'. To represent this state, computer scientists use the values of 0 (off) and 1 (on); we refer to this value as a bit. The term "bit" was coined from mathematician Claude Shannon’s research in the 1940s[1].

Half of a byte (four bits) is referred to as a nibble. A word is a standard number of bytes that memory is addressed with. Memory can only be addressed by multiples of the size of a word, and the size of a word is dependent on the architecture. For example: a 16-bit processor has words consisting of two bytes (8 x 2 = 16), a 32-bit processor has words that consist of four bytes (4 x 8 = 32), etc.

The eight bits making up each byte can represent any number from 0 to 255. We obtain this number of possible values, which is 256 when including the 0, by raising the possible values of a bit (two) to the power of the length of a byte (eight); thus, 28 = 256 possible values in a byte.

While there are many different ways to express the value of a byte, the three main types are hexadecimal, binary, and decimal. Hexadecimal is probably the most common method for explicit editing of a binary file, due largely to the fact that the system can express 256 different numbers in only two characters. For example, ff is the largest hexadecimal number, with a value of 255, while 00 is the lowest, having the value of 0.

In the screenshot of the Hexer binary editor at the beginning of this article, the first eight bytes are {66,ea,08,00,00,00,c0,07}. This sequence of numbers could be expressed in the decimal system as {102,234,8,0,0,0,192,7}.

Hexadecimals are often expressed with 0x preceding the number, such as 0xf8, in order to denote the fact that the number is in the hexadecimal format. This method is most often used in calculators and compilers, where the computer need to be told what format it is supposed to be reading. If the computer is not told this, then it may interpret the number as a variable or decimal number, resulting in a build-time error or a bug in the software.

Bytes can be used to represent a countless array of data types, from characters in a string of text, to the assembled and linked machine code of a binary executable file, which is the language that programs use to tell the computer how to act. Every file, sector of system memory, and network stream is composed of bytes.

Perhaps the oldest formation of bytes was plain text (without any punctuation) as used in telegrams. To compensate for the absence of basic punctuation, telegrams in times past would often use the word "STOP" to represent a period.

In computers, plain text came to mean a string, file, or byte array that is printable, consisting only of standard alphanumeric bytes and a few control bytes such as tab, carriage return, or line feed. Plain text was not supposed to include any bytes that a printer would not know how to handle. The actual value of each character has varied in years past. Today, however, we have the American Standard Code for Information Interchange (ASCII), which allows data to be readable when being transmitted through different mediums, such as from one operating system to another. For instance, a user who typed a plain text document in Linux would usually be able to view or print the same file on a Macintosh computer. One example of ASCII would be the capital letters of the English language, which range from 101 for "A" to 127 for "Z".

Endianness

When multiple contiguous bytes represent a single number, there are two possible opposite "orderings" of the bytes; the particular ordering used is called endianness. Just as some natural languages are written from left to right, such as English, while others are written from right to left, such as Hebrew, bytes can be arranged "big end first", or Big Endian (with the most significant bit in lower memory) or "little end first", or Little Endian (with the least significant bit at the lower memory address). The names are derived from the book Gulliver's Travels, in which the Lilliputians' forefront political concern was whether eggs should be opened from the little end or the big end.[2]. A similar ordering decision exists for the bits within a byte; it tends to be called simply bit ordering.

Differences in endianness arose among various computer architectures. For example, the Intel x86 architecture used for IBM compatible PCs is little endian, whereas SPARC (Solaris) architectures are big endian. Even programming languages which run on virtual machines, such as Java or C sharp, have endianness. Java, which was developed first on Unix machines that tended to be big endian, uses a big endian virtual machine (a.k.a. runtime), whereas C sharp, developed by Microsoft for Intel x86 computers, uses a little endian runtime.

In the past, differences in endianness were a hazard when transferring numbers (or any kind of information) between two computers using different architectures, and many errors arose due to mistakes in translating bytes and bits incorrectly. Since the late 1990's, endianness has receded as a problem due to the widespread adoption of eXtensible Markup Language (XML) as a kind of lingua franca for transferring information between computers. XML is a standardized way of representing numbers, and indeed any kind of information at all, as strings of plain text.

Word origin and ambiguity

Although the origin of the word 'byte' is unknown, it is believed to have been coined by Dr. Werner Buchholz of IBM in 1964. It is a play on the word 'bit', and originally referred to the number of bits used to represent a character.[3] This number is usually eight, but in some cases (especially in times past), it can be any number ranging from as few as 2 to as many as 128 bits. Thus, the word 'byte' is actually an ambiguous term. For this reason, an eight bit byte is sometimes referred to as an 'octet'.[4]

Sub-units

Because files are normally many thousands or even billions of times larger than a byte, other terms designating larger byte quantities are used to increase readability. Metric prefixes are added to the word byte, such as kilo for one thousand bytes (kilobyte), mega for one million (megabyte), giga for one billion (gigabyte), and even tera, which is one trillion (terabyte). One thousand megabytes compose a terabyte, and even the largest consumer hard drives today are only three-fourths a terabyte (750 'gigs' or gigabytes). The rapid pace of technological advancement may make the terabyte commonplace in the future, however.

Conflicting definitions

Traditionally, the computer world has often used a value of 1024 instead of 1000 when referring to a kilobyte. This was done because programmers needed a number compatible with the base of 2, and 1024 is equal to 2 to the 10th power. Typically, storage space is measured with a base of 2, whereas data rates generally uses a base of 10. Thus, engineers in one field of computer science may use the same term when referring to different units of measurement (numbers of bytes).

Due to the large confusion between these two meanings, an effort has been made by the International Electrotechnical Commission (IEC) to remedy this problem. They have standardized a new system called the 'binary prefix', which replaces the word 'kilobyte' with 'kibibyte', abbreviated as KiB, to mean 1024 bytes. This solution has since been approved by the IEEE on a trial-use basis, and may prove to one day become a true standard.[5]

While the difference between 1000 and 1024 may seem trivial, one must note that as the size of a disk increases, so does the margin of error. The difference between 1TB and 1TiB, for instance, is approximately 10%. As hard drives become larger, the need for a distinction between these two prefixes will grow. This has been a problem for hard disk drive manufacturers in particular. For example, one well known disk manufacturer, Western Digital, has recently been taken to court for their use of the base of 10 when labeling the capacity of their drives. This is a problem because labeling a hard drive's capacity with the base of 10 implies a greater storage capacity when the consumer may assume it refers to the base of 2. [6]

Table of prefixes

Metric (abbr.) Value Binary (abbr.) Value Difference* Difference in bytes
byte (B) 100  = 10000 byte (B) 20  = 10240
0%
0
kilobyte (KB) 103  = 10001 kibibyte (KiB) 210 = 10241
2.4%
24
megabyte (MB) 106  = 10002 mebibyte (MiB) 220 = 10242
4.9%
48,576
gigabyte (GB) 109  = 10003 gibibyte (GiB) 230 = 10243
7.4%
73,741,824
terabyte (TB) 1012 = 10004 tebibyte (TiB) 240 = 10244
10%
99,511,627,776
petabyte (PB) 1015 = 10005 pebibyte (PiB) 250 = 10245
12.6%
125,899,906,842,624
exabyte (EB) 1018 = 10006 exbibyte (EiB) 260 = 10246
15.3%
152,921,504,606,846,976
zettabyte (ZB) 1021 = 10007 zebibyte (ZiB) 270 = 10247
18.1%
180,591,620,717,411,303,424
yottabyte (YB) 1024 = 10008 yobibyte (YiB) 280 = 10248
20.9%
208,925,819,614,629,174,706,176

*Increase, rounded to the nearest tenth

Related topics

References

  1. " Claude Elwood Shannon" (biography). The History of Computing Project (2005). Retrieved on 2007-05-12.
  2. What is big-endian? - A Word Definition From the Webopedia Computer Dictionary (Accessed April 15th, 2007).
  3. Dave Wilton (2006-04-8). Wordorigins.org; bit/byte.
  4. Bob Bemer (Accessed April 12th, 2007). Origins of the Term "BYTE".
  5. IEEE Trial-Use Standard for Prefixes for Binary Multiples (Accessed April 14th, 2007).
  6. Nate Mook (2006-06-28). Western Digital Settles Capacity Suit.